An attenuation cell is provided for use in a switched attenuator. The attenuation cell includes an attenuation path that has an input, a first switch, a resistive network, a second switch, and an output. The resistive network provides a desired attenuation from the input to the output. The attenuation cell also includes a bypass path in parallel with the attenuation path with a bypass switch between the input and the output. The attenuation cell also has a shunt switch coupled between the resistive network and a reference node to selectively connect the resistive network to the reference node.

A termination/attenuation network applies to an input of a set-top box a MOCA channel signal having a narrow band of frequencies and included in RF signals having a wide band of frequencies received via a cable from a satellite antenna. The network includes a pair of series resistors and a parallel resistor coupled to a junction terminal between the pair of series resistors in a T-shaped configuration. A series-pass band-pass filter (L1, C2) bypasses the pair of series resistors and a parallel band stop filter (L2, C1) decouples the parallel resistor at the frequency band of the MOCA channel signal for selectively reducing attenuation at the frequency band of the MOCA channel signal.

A termination/attenuation network applies to an input of a set-top box a MOCA channel signal having a narrow band of frequencies and included in RF signals having a wide band of frequencies received via a cable from a satellite antenna. The network includes a pair of series resistors and a parallel resistor coupled to a junction terminal between the pair of series resistors in a T-shaped configuration. A series-pass band-pass filter (L1, C2) bypasses the pair of series resistors and a parallel band stop filter (L2, C1) decouples the parallel resistor at the frequency band of the MOCA channel signal for selectively reducing attenuation at the frequency band of the MOCA channel signal.

A bandstop filter is provided that includes an input port, a series bandpass resonator, a first capacitor, a bandstop resonator, a second capacitor and an output port. The combination of the first capacitor, the bandstop resonator and the second capacitor comprises a bandstop impedance magnitude and a bandstop impedance phase. The bandpass resonator impedance magnitude is substantially equal to the bandstop impedance magnitude. The bandpass resonator impedance phase is substantially 180 out of phase with the bandstop impedance phase. The series bandpass resonator, the first capacitor, the bandstop resonator and the second capacitor operate as a band stop for a predetermined frequency within the frequency band.

A bandstop filter is provided that includes an input port, a series bandpass resonator, a first capacitor, a bandstop resonator, a second capacitor and an output port. The combination of the first capacitor, the bandstop resonator and the second capacitor comprises a bandstop impedance magnitude and a bandstop impedance phase. The bandpass resonator impedance magnitude is substantially equal to the bandstop impedance magnitude. The bandpass resonator impedance phase is substantially 180 out of phase with the bandstop impedance phase. The series bandpass resonator, the first capacitor, the bandstop resonator and the second capacitor operate as a band stop for a predetermined frequency within the frequency band.

A Wilkinson power divider includes: -type LPFs connected to an input terminal; a T-type HPF having one end connected to one of the -type LPFs and having another end connected to a carrier amplifier; another T-type HPF having one end connected to another one of the -type LPFs and having another end connected to a /4 line; and an isolation resistor connected to connection points.

A Wilkinson power divider includes: -type LPFs connected to an input terminal; a T-type HPF having one end connected to one of the -type LPFs and having another end connected to a carrier amplifier; another T-type HPF having one end connected to another one of the -type LPFs and having another end connected to a /4 line; and an isolation resistor connected to connection points.

An attenuation cell is provided for use in a switched attenuator. The attenuation cell includes an attenuation path that has an input, a first switch, a resistive network, a second switch, and an output. The resistive network provides a desired attenuation from the input to the output. The attenuation cell also includes a bypass path in parallel with the attenuation path with a bypass switch between the input and the output. The attenuation cell also has a shunt switch coupled between the resistive network and a reference node to selectively connect the resistive network to the reference node.

An attenuation cell is provided for use in a switched attenuator. The attenuation cell includes an attenuation path that has an input, a first switch, a resistive network, a second switch, and an output. The resistive network provides a desired attenuation from the input to the output. The attenuation cell also includes a bypass path in parallel with the attenuation path with a bypass switch between the input and the output. The attenuation cell also has a shunt switch coupled between the resistive network and a reference node to selectively connect the resistive network to the reference node.

A signal interconnect includes a transmission line, a termination circuit coupled to the transmission line, and a high pass filter circuit coupled in series along the transmission line. The high pass filter circuit includes a first resistive circuit and a first capacitive circuit coupled in parallel. The first resistive circuit has a resistance based on a difference between a resistance of the transmission line at a high frequency and a resistance of the transmission line at a low frequency.